以pH敏感相分离高分子为载体的酶联荧光免疫分析法测定人IgG

p H敏感高分子因其独特的 p H敏感性质而在药物的控制释放 [1,2 ] 、分子分离 [3 ] 以及生物传感器 [4 ]等方面得到应用 .应用于免疫分析时 ,要求 p H敏感高分子在溶液 p H 7.4左右波动时做出响应 ,过多偏离生理 p H会对免疫反应生成的抗原 -抗体复合物造成不同程度的破坏 .目前 ,p H敏感高分子并未在免疫分析中广泛应用 ,这主要是由于高分子的相转变 p H大多在 4或 1 0左右[5,6] .我们 [7] 曾合成了3 7℃下相转变 p H在 5 .6左右的 p H敏感高分子 ,并将其作为免疫反应载体 ,建立了乙肝表面抗原的分析系统 ,虽然其相转变 p H比以往的高…     

可控相转变温度热敏高分子的制备及其在免疫分析中的应用

合成了一种新型的快速响应热敏高分子聚N－异丙基丙烯酰胺－丙烯酰胺[P(NIP-co-AA)]，通过改变丙烯酰胺的含量可以改变高分子的临界溶解温度（LCST），使之用于不同用途。其中，将相转变温度（Ttr)在37℃的热敏高分子用于免疫分析的载体，建立了夹心型荧光免疫分析兔IgG的新方法。与聚N－异丙基丙烯酰胺（PNIP）作载体相比，两灵敏度相当，但由于相转变温度的提高，使得免疫反应的温度更接近于生物体的生理环境，并使免疫反应速率得到提高。该方法线性范围为0-1000μg/L；检出限为10μg/L。用于兔血清中兔IgG的测量，结果令人满意。     

新型pH敏感高分子相分离荧光免疫分析法测定兔血清中IgG

通过将N-异丙基丙烯酰胺（NIP）、甲基丙烯酸丁酯（BMA）和甲基丙烯酸（MAA）共聚得到了一种新型的pH敏感高分子,其相转变pH（pHtr）在37℃下为6.0;当溶液pH〉6.0时,高分子溶解;pH〈6.0时,高分子很快从溶液中沉淀出来。在竞争型免疫测定中,偶联在高分子上的兔免疫球蛋白G（IgG）和标准兔IgG在溶液中竞争性地与有限量的异硫氰酸荧光素标记抗体反应,根据pHtr以下免疫复合物沉淀的特性进行分离,建立了均相免疫反应、异相分离的兔IgG新型测定方法,线性范围为100—1000μg／L;检出限为10μg/L。方法灵敏、快速且操作简便,由于pHtr较之以前合成的敏感高分子更接近于中性,分离时可降低对抗原-抗体免疫复合物造成的损坏。用于兔血清中免IgG的测量,结果令人满意。     

带活性末端的热敏高分子的制备及其在荧光免疫分析中的应用

合成了带有活性末端的寡聚N-异丙基丙烯酰胺(ONIPAAm),并考察了其温度敏感性质.以ONI-PAAm作为免疫分析的载体与鼠IgG偶联,以四磺基铁酞菁为标记物,以羊抗鼠IgG抗体为分析模型,建立了竞争型热敏相分离荧光免疫分析新系统.羊抗鼠IgG抗体在0～1500ng/mL范围内与体系相对荧光强度呈良好的线性关系,检测限为2ng/mL.     

以萘酰亚胺衍生物基荧光高分子为载体和指示剂的 相分离免疫分析方法

以4-甲氧基-N-(2-N’,N’-二甲基氨基乙基-N’-烯丙基)萘二甲酰亚胺氯化铵(DMNAA)为荧光单体, 合成了一种pH敏感荧光高分子聚N-异丙基丙烯酰胺-4-甲氧基-N-(2-N’,N’-二甲基氨基乙基-N’-烯丙基)萘二甲酰亚胺氯化铵-N,N-二甲基氨丙基甲基丙烯酰胺[P(NIP-DMAPM-DMNAA)]. 采用共聚法将日本血吸虫抗原(SjAg)固定在P(NIP-DMAPM-DMNAA)上, 制备P(NIP-DMAPM-DMNAA)-SjAg连接物, 与日本血吸虫抗体(待测, SjAb)发生免疫反应后, 调节pH值, 使荧光高分子相变分离高分子-免疫组分连接物, 最后, 利用蛋白A对抗体的亲和性捕获P(NIP-DMAPM-DMNAA)-SjAg-SjAb, 通过测定高分子自身的荧光信号来定量 SjAb. 该新型高分子具有良好的荧光特性, 对pH响应快速, 37 ℃下相转变pH值为7.2, 分离免疫复合物时造成的损害低. 与传统相分离免疫分析比较, 新方法通过高分子相变分离和蛋白A捕获双重分离作用, 消除了非特异性组分和未反应的特异性免疫成分等的干扰; 利用高分子自身的荧光信号检测, 无须另外的标记物, 大大提高了免疫分析的简便性. 以日本血吸虫抗体为分析对象, 测得线性范围为1～1500 ng/mL, 抗体检出限为1.3 ng/mL, 相对标准偏差为3.6% (n＝10), 结果令人满意.     

基于荧光体系的酶联免疫吸附分析法的研究进展

酶联免疫吸附分析（Enzyme linked immunosorbent assay, ELISA）作为一种重要的免疫分析方法,具有高通量、信号读取方便、操作简单和成本低廉等优点,广泛应用于环境监测、食品安全检测以及医疗诊断等领域。然而,由于受比色显色原理的限制,传统ELISA的检测灵敏度难以提高。为了解决此问题,研究者开发了多种类型的新型检测体系。其中,荧光方法由于具有灵敏度高、操作简单以及响应快速等优势,引起了广泛关注。目前,多种新型荧光材料已被广泛用于构建ELISA,促进了ELISA在分析化学和生物医疗检测中的应用。本文详细介绍了有机小分子、硅/碳纳米粒子、金属纳米簇和量子点等荧光材料构建的ELISA,根据使用标记酶的不同,介绍了以碱性磷酸酶、辣根过氧化物酶等酶作为标记酶的ELISA,评述了近五年来荧光材料在构建ELISA方面的研究进展,并对其应用前景与发展趋势进行了展望。     

新型pH敏感相分离高分子的制备及其在免疫分析中的应用

聚Ｎ 异丙基丙烯酰胺 (ＰＮＩＰ)温度敏感高分子以其独特的温度敏感性质已成功地应用于免疫分析[1～ 6] .但这类温度敏感相分离免疫分析的反应温度必须控制在ＰＮＩＰ的相转变温度 ( 31℃ )以下 ,这不可避免地会影响免疫反应速率 .ｐＨ敏感高分子是另一类对环境敏感的智能型高分子 ,在其相转变ｐＨ值附近发生沉淀与溶解的可逆性变化 .目前 ,ｐＨ敏感高分子在免疫分析中的应用并没有受到重视 ,研究得较少[7] .这主要是由于 ｐＨ敏感高分子的相转变 ｐＨ值大都在 3左右 ,在此ｐＨ条件下 ,免疫反应生成的抗原 抗体免疫复合物会受到不同程度的…     

热敏相分离荧光免疫分析乙肝表面抗原的新方法

以N-异丙基丙烯酰胺为单体,将水溶性热敏高分子聚异丙基丙烯酰胺(PNIP)和抗体偶联,用异硫氰酸荧光素标记羊抗人乙肝表面抗原抗体,建立了夹心型热敏相分离荧光免疫分析乙肝表面抗原(HBsAg)的新方法.评价了抗体在PNIP上的固定效率和非特异性吸附情况.HBsAg在0.5～100μg/mL范围内与体系荧光强度呈良好的线性关系,检出限为10ng/mLHBsAg.该方法既具有均相免疫分析的快速性,又有固相免疫分析的高灵敏度.用于乙肝病人血清中HBsAg水平的测定,结果令人满意.     

基于手性联萘酚高分子对汞离子的荧光传感器

手性联萘酚高分子由单体(R)-3,3′-二炔基-6,6′-二正丁基-2,2′-联萘酚(R-M-1)和对苯二叠氮(M-1)通过CuAAC反应得到,通过1HNMR、13CNMR、FTIR、旋光度、GPC、热分析、荧光光谱等方法对单体和高分子进行了结构表征和性能测试。该高分子是通过"Click"反应得到的手性联萘酚高分子,本文探讨了手性高分子传感器对各种金属离子的荧光传感性质,结果表明,与其他离子如K+、Mg2+、Pb2+、Co2+、Ni2+、Ag+、Cd2+、Cu2+、Zn2+等相比,Hg2+几乎使高分子荧光完全淬灭。这表明,以三氮唑基团作为连接基团和识别位点的高分子可作为有效识别Hg2+的荧光化学传感器。     

基于pH敏感相分离技术的新型荧光免疫测定体系

In this paper, it was discovered that a novel pH-sensitive copolymer of N-isopropylacrylamide (NIP) and N-(3-dimethylaminopropyl)methacrylamide (DMAPM) could be gotten by polymerization. The phase transition pH (pHtr) of P(NIP-DMAPM) polymer was found to be 7.4 at 37℃. The polymer was precipitated out of water above a critical pH=7.4 and re-dissolved below pH----7.4. The characteristic of this polymer made it possible to carry out the immunochemical steps of an immunoassay in a true solution and then to quickly separate the resulting product from the reaction mixture. In a competitive fluorescence immunoassay, the standard rabbit IgG and rabbit IgG immobilized on P(NIP-DMAPM) first competitively reacted with the fluorescein isothiocyanate (FITC) labeled antibody, then the pH of solution was adjusted above the pHtr of polymer to precipitate the polymer-immune complex,and the polymer-immune complex precipitate was separated and re-dissolved by the adjustment of pH, finally the FITC-labeled antibody in the immune complex was quantified by fluorescence measurement. The calibration graph for rabbit IgG was linear over the range of 100-1000 ng/mL with a detection limit of 11 ng/mL. The method is rapid, sensitive and simple. Owing to neutral pHtr of P(NIP-DMAPM), the damage to antigen-antibody immune complex was greatly decreased in the course of separation. In addition, a sandwich enzyme-linked fluorescence immunoassay method for the determination of human IgG was also developed, showing that the pH-sensitive phase separating immunoassay could be performed in the competitive method as well as the sandwich method.     

芯片式流通池用于顺序注射可更新表面荧光免疫法测定人血清中的IgG

采用芯片式流通池作为非均相免疫反应和原位固相荧光检测的场所,用双岔光纤将芯片式流通池与荧光光度计耦联,以双抗夹心式非均相免疫反应的模式,研究建立了测定人血清中IgG的顺序注射可更新表面非均相免疫分析新方法.     

Comparison of Immobilization Modes in pH-Sensitive Phase Separation Immunoassay

Three immobilization modes of antigen to the polymers in the pH‐sensitive phase separation immunoassay were investigated and compared. The results showed that the immobilization mode in the presence of N‐ethyl‐N′‐(3‐dimethylaminopropyl)carbodiimide hydrochloride (EDCI) rendered the most desirable results. The immobilization efficiencies and immunological reaction activities of immobilized antigen of this mode were improved over the other two modes. The novel immobilization mode by EDCI was used in the pH‐sensitive phase separation immunoassay for rabbit IgG (Ag). In the competitive immunoassay, immobilized Ag and the standard Ag (or sample) competed for binding to a horseradish peroxidase labeled antibody at 37°C in a homogeneous format. After changing the pH to separate the polymer‐immune complex, the complex precipitate was re‐dissolved and determined by coupling with the color reaction of hydrogen peroxide and o‐phenylenediamine. The linear range of this determination was between 100–1400 ng/mL. Compared to the traditional enzyme‐linked immunosorbent assays (ELISA) using the same reactants, the proposed method was quiet fast (the time decreased from 100?120 to 30 min) and showed similar sensitivity, i.e., 6.0 ng/mL.     

A Novel Temperature‐Responsive Polymer as a Gene Vector

A temperature‐responsive polymer poly{2‐(dimethylamino)ethyl methacrylate‐co‐[cis‐butenedioic anhydride‐poly[(N‐isopropylacrylamide)‐co‐(butyl methacrylate)]]} (PDMNIB) was synthesized by free radical polymerization. The polymer had a significant temperature‐responsive behavior with a lower critical solution temperature (LCST) at 20 °C. Gel retardation assay showed that PDMNIB could efficiently interact with DNA. Dynamic light scattering (DLS) and zeta potential measurement indicated that the average sizes and the surface electric charges of the PDMNIB/DNA complexes could be changed by temperature. Due to the thermosensitive interaction between PDMNIB and DNA, the gene transfection efficiency of PDMNIB could be improved by temperature.

     

Gold Nanoparticles Functionalized by a Dextran‐Based pH‐ and Temperature‐Sensitive Polymer

A dextran‐based dual‐sensitive polymer is employed to endow gold nanoparticles with stability and pH‐ and temperature‐sensitivity. The dual‐sensitive polymer is prepared by RAFT polymerization of N‐isopropylacrylamide from trithiocarbonate groups linked to dextran and succinoylation of dextran after polymerization. The functionalized nanoparticles show excellent stability under various conditions and can be stored in powder‐form. UV and DLS measurements confirm that the temperature‐induced optical changes and aggregation behaviors of the particles are strongly dependent on pH.